The ability to generate transgenic plants without regard to cultivar or genotype can be considered a holy grail of cereal crop transformation. Despite years of effort, it has been remarkably difficult to develop efficient methods for transformation of cereals. The preferred methods generally involve Agrobacterium-mediated transformation of cultured tissue or immature embryos, followed by callus culture to regenerate plants (reviewed inShrawat and Lörz, 2006). Unfortunately, the capacity of Agrobacterium to infect monocots is limited to a narrow range of genotypes and the utility of the technique is further limited by the recalcitrance of many genotypes to callus formation and regeneration. ABreakthrough Report from Lowe et al. (2016) describes an exciting new approach to boost monocot transformation rates in a broad range of genotypes.
Lowe et al. took advantage of morphogenic genes to create a biological context conducive to transformation efficiency. Their transformation constructs included Zea mays (maize)Baby boom (Bbm) and Wuschel2 (Wus2), homologs of which in Brassica napus and Arabidopsis thaliana promote transition from vegetative to embryonic growth (Boutilier et al., 2002; Zuo et al., 2002). The authors used these constructs for Agrobacterium-mediated transformation of immature embryos from four maize inbred lines. These lines showed markedly higher transformation rates, going from 0-2% in the controls to 25-51% in the presence of Wus andBbm.
Lowe et al. designed their constructs with flanking LoxP recombination sites and CRErecombinase driven by a drought-inducible promoter. Accordingly, desiccation treatment of the transgenic tissue allowed excision of the Wus, Bbm, and CRE expression cassette. The final transformation efficiency, accounting for all three stages of the process (transformation, excision, regeneration of healthy plants), for the four tested lines ranged from 3-11% (calculated based on the number of initial embryos used and the final number of healthy transgenic plants obtained). This level of recovery of transgenic plants is high enough to be useful for large-scale production both for commercial purposes and in primary research.
Among a panel of 50 maize inbred lines, 33 successfully produced transgenic calli upon transformation with Wus and Bbm. Thus, although not yet fully genotype independent, this approach greatly increases the range of cultivars available for transformation. Importantly, it can be used on a variety of initial tissues. It can be costly and time-consuming to obtain a consistent supply of immature embryos, but Lowe et al. obtained healthy transgenic plants by directly transforming mature seed tissues or seedling leaf segments (see Figure) – skipping the usual explant culture step before transformation and further facilitating large-scale transformation efforts.
This morphogenic-gene based approach also worked in other monocot crops, increasing transformation frequency from 1.9% to 18% in sorghum and from 0-3% to 15-43% in rice, whereas sugarcane callus showed an almost fantastical increase from 2% to 274/885% (i.e., multiple transgenic events recovered per initial starting tissue). In extending the range of species, genotypes and tissues that can be used for efficient transformation, Lowe et al. have given us a beautiful example of what can be accomplished by combining basic research, technical expertise, and knowledge of practical problems facing mainstream applications.